UA121718C2 - ISOLATING BREATHING APPARATUS - Google Patents

Abstract

The invention belongs to the technical means of protecting the respiratory organs, which ensure the vital activity of a person in an atmosphere unsuitable for breathing, and concerns an isolating breathing apparatus with a closed circuit of the breathing mixture circulation (self-contained self-rescue, SCSR), equipped with a tank with compressed oxygen. In the breathing apparatus, the efficiency of processing the gas mixture exhaled by the user and the quality of the inhaled breathing mixture have been improved by introducing the appropriate inventive structure of the breathing mixture circulation circuit with the use of simultaneous mechanical pressure on the exhalation bag and the inhalation bag and additional cooling.

Description

The invention belongs to the technical means of protection of respiratory organs, which ensure the vital activity of a person in an atmosphere unsuitable for breathing, and concerns an isolating breathing apparatus with a closed circuit of the circulation of a breathing mixture (pneumatic breathing apparatus, 5SZNA), equipped with a tank with compressed oxygen.

Self-contained breathing apparatuses are essential tools for repair and rescue work in various industries. The requirements for their quality and reliability to ensure the safety of users, as well as for functionality and ergonomics are constantly increasing, so designers and manufacturers make significant efforts to develop and improve various systems and components of these products.

The subject of the present invention relates to the composition and design of elements of the breathing mixture circulation circuit.

Numerous technical solutions are known from the prior art, aimed at improving the processing of the gas mixture exhaled by the user and its preparation for inhalation by the user.

Thus, in the British application В 201516077 (МПК: Аб2В 09/00, published on 10.09.2015) a breathing apparatus is described, in the closed case of which there are elements connected in series (in the direction of the movement of the flow) of the closed loop of the circulation of the breathing mixture: a device for connecting the face masks, absorbent cartridge, breathing bag and cooler. With this scheme, the gas mixture exhaled by the user directly enters the absorbent cartridge. Although modern absorbing cartridges have an improved design, they still offer a certain resistance to the flow of the gas mixture exhaled by the user, which is especially felt by the user in the final phase of exhalation. In addition, with the described layout of the circulation circuit, the absorbent cartridge processes a largely variable flow of the exhaled mixture, as a result of which its active substance during the breathing cycle has a different absorption capacity, which decreases when the speed of washing the absorbent grains with the flow of the gas mixture increases. At the same time, part of the respiratory flow passes through the absorbent cartridge without being cleaned.

When inhaling, the user also experiences difficulty, which increases with increasing physical activity and associated pulmonary ventilation, as he is forced to overcome the resistance of the cooler to the flow of the breathing mixture.

From Internet-Publication pir://tedargedtei.gy/1-22532.pIt are known insulating breathing apparatus with a circular air circulation scheme, in which, in addition to the main breathing bag located between the absorbent cartridge and the cooler, there is an additional bag located between the exhalation valve and a regenerative cartridge. This bag serves to reduce exhalation resistance by "smoothing" the peak value of volumetric air flow. They do not solve the problem of possible inhalation of toxic gases due to the loose fit of the mask to the user's face.

From the level of technology, the popular German isolation breathing apparatus Ogadeg is also known

RBBO Vb o 4 orie (material of the company Ogadeg Zaye3u Ai 4 bo. Kodaa pErzv/Lymly agaedeg.sot/Rhodysiv/Sopiepurez-ra4-riiv-ri-9044832-y5-ep.rag 2009), in the case of which the absorbing cartridge and the cooler are also are located directly next to the exhalation and inhalation nozzles, respectively, as a result of which through the cartridge an uneven flow of the processed gas mixture is pumped. The breathing bag connected between the absorbent cartridge and the cooler is equipped with a pressure device to create excess pressure in the circuit, which prevents contaminated gases from the surrounding atmosphere from entering the user's respiratory tract during inhalation. Condensate formed in the cooler is diverted to the collector through the drain valve of the breathing bag.

The pressure device is structurally designed in such a way that the assembly and disassembly of the breathing bag with the pressure system is difficult.

From the application OE102016000268 JSC (applicant Ogadeg Zaieu DS Ya So. Kdaa; IPC: Ab2B 7/02, published on 20.07.2017) an elastic breathing bag in the form of a parallelepiped with a pressure device acting on its perpendicular fixed base, placed between the absorbent cartridge and the cooler, is known the long face of the pressure plate, the long side of which is installed on the axis of rotation at a certain distance from the base of the bag.

Pressing is carried out by a drive device in the form of a spring. The spring can be installed with a torsional action along the axis of rotation of the pressure plate or with a tensional action through various lever mechanisms.

The disadvantage of the breathing apparatus mentioned above is that they provide for the direct supply of the exhaled gas mixture to the absorbent cartridge, which causes the flow of the exhaled mixture to flow through it, which is largely variable during the breathing cycle.

The task of the invention is to improve the quality of the breathing mixture in the isolation breathing apparatus and to improve the comfort of breathing for the user of the isolation breathing apparatus by introducing the corresponding inventive structure of the circulation circuit of the breathing mixture.

The task is solved by the fact that in the isolating breathing apparatus, which contains a body, equipped with a face mask and a connection box with inhalation and exhalation hoses, inside which there is a system for processing and supplying a respiratory mixture, containing breathing bags for inhalation and exhalation, an absorbent cartridge, a cooler, system of oxygen supply and forced circulation of the respiratory mixture, which includes an oxygen cylinder, an oxygen distribution unit with a reducer and a constant oxygen supply device and a lung machine connected to the medium pressure zone, as well as a device for creating excess pressure in the breathing mixture circulation circuit, according to the invention, the closed breathing mixture circulation circuit includes connected in series: inhalation hose, connection box, face mask, exhalation hose, exhalation valve, exhalation bag, absorbent cartridge, cooling separator, cooler, inhalation bag, valve inhalation, and the separator contains a hollow cooling channel made of heat-conducting material, which has thermal contact with the device body, for passing the hot breathing mixture from the absorbent cartridge to the cooler and a channel separated from the cooling channel for diverting the counterflow of condensate from the gas mixture cooler, an inhalation valve located in the housing between the inhalation port and the inhalation bag, and the exhalation valve located in the housing between the exhalation bag and the exhalation nozzle, the inhalation bag and the exhalation bag are placed in the upper part of the body directly under the inhalation and exhalation valves, respectively, the outlet of the lung machine and the outlet of the constant oxygen supply device are connected to the inhalation nozzle after the inhalation valve relative to the direction of the flow of the respiratory mixture, the device for creating an excess of pressure in the respiratory mixture circulation circuit contains a pressure plate installed with the possibility of simultaneous mechanical action on the exhalation bag and the inhalation bag and the pneumo-mechanical feedback system associated with it, containing a spring-loaded lever with a variable pressure force depending on the filling of the breathing bags.

In the preferred form of implementation of the invention, the cooling separator is made in the form of a bag made of flexible heat-conducting material, equipped with an inlet pipe and

With an outlet pipe with flanges for connecting to the lower parts of the absorbent cartridge and the cooler, respectively, and in the lower part of the bag there is a separating perforated partition, under which a hygroscopic element is placed for absorbing condensate from the cooler.

In the preferred form of implementation of the invention, the inhalation valve and the exhalation valve are structurally identical and contain a plastic seat and a mushroom-shaped elastic petal, and the working surface of the seat is concave in the form of a fragment of the side surface of the cylinder.

The features and advantages of the invention are explained in more detail below with reference to the drawings. They schematically depict:

Fig. 1 Structural diagram of an isolating breathing apparatus with a closed circuit of the respiratory mixture circulation,

Fig. 2 Cooling separator.

In fig. 1 presents a structural diagram of the preferred form of implementation of the insulating breathing apparatus according to the invention, which contains a housing 1, in which the elements of a closed breathing circuit connected in series in the direction of the movement of the gas mixture are placed: exhalation nozzle 2, exhalation valve Z, exhalation bag 4, absorbent cartridge 5 , a cooling separator 6, a cooler 7 of the respiratory mixture with a coolant placed in the glass in the form of a solid bar or pieces of ice, chilled gel, etc., inhalation bag 8, inhalation valve 9, inhalation nozzle 10, as well as a hose system, which includes a flexible inhalation hose 11 connected to the inhalation nozzle 10, a connecting box 12, a face mask 13 and connected to nozzle 2 exhalation flexible hose 14 exhalation.

The ends of the hoses 11 and 14, together with the nozzles 2 and 10 installed in the body, form identically designed rotary connecting nodes, which provide the possibility of rotating the ends of the hoses relative to the nozzles, for example, if it is necessary to remove the device from the shoulders and push it in front of you in a narrow horizontal channel. Due to the rotation of the ends of the hoses relative to the nozzles, the otherwise possible threat of local bending of the hoses and cessation or deterioration of the passage of the breathing mixture is eliminated.

In the lower part of the case, there is a cylinder 15 with compressed oxygen, connected to the oxygen distribution unit 16, in which a reducer with a zone 17 of medium pressure is installed, to which a pulmonary machine 18 and a device 19 for supplying a constant flow of oxygen are connected.

In contrast to the solutions of the prior art, according to which the outputs of the lung machine and the device for supplying a constant flow of oxygen are connected, as a rule, to the inhalation bag, according to the invention, the outputs of the lung machine 18 and the device 19 for supplying a constant flow of oxygen are connected to the nozzle 10 inhalation after valve 9 inhalation relative to the direction of movement of the flow of the breathing mixture. This connection is motivated by the need to eliminate the so-called "dead space" that is formed in the hose system during exhalation due to at least partial filling of the connecting box 12 and the inhalation hose 11 with the exhaled gas mixture. At the beginning of the next inhalation phase, the user inhales the depleted gas mixture from this space and only then - the processed in the absorption cartridge and the oxygenated breathing mixture from the inhalation bag. Thanks to the supply of oxygen from the constant flow supply device 19 after the inhalation valve 9, an oxygen-enriched gas mixture is constantly present in the hose system, which increases the protective function of the breathing apparatus, and also creates an additional "drive" for the circulation of the gas mixture in the circuit.

According to the invention, the inhalation and exhalation valves are structurally identical and contain each plastic seat and a mushroom-shaped elastic petal, and the working surface of the seat is concave in the form of a fragment of the side surface of the cylinder. This is done to ensure unambiguous conditions for bending the valve petal in the direction of the flow of the breathing mixture. Thanks to the concave surface of the saddle, the areas of the elastic petal that bend during the passage of the breathing mixture are set uniquely, and not randomly. In addition, a tighter fit of the petal is ensured when the valve is closed.

Exhalation bag 4 and inhalation bag 8 are structurally located next to each other in the upper part of the housing, directly below the exhalation valve C and the inhalation valve 9, respectively.

The absorbent cartridge 5 is located directly under the exhalation bag 4, and the cooler 7 is located directly under the inhalation bag 8. An additional advantage of placing relatively heavy structural elements, which are the absorbent cartridge 5 and the cooler 7, not in the upper part of the device body, should be considered a downward shift of the reduced center masses of the respiratory apparatus.

Directly above exhalation bag 4 and inhalation bag 8 is a pressure plate 20 of a device designed to create excess pressure in the inhaling part of the respiratory mixture circulation circuit, as well as to equalize pressure differences in the exhalation part of the circulation circuit in

From the user's breathing process.

The applicant carried out numerous laboratory and field studies related to the mutual placement and constructive execution of the elements of the circulation circuit, which determine the quality of processing of the breathing mixture and the comfort of the user during the inhalation and exhalation phases of the breathing cycle - the absorbent cartridge, the cooler, the breathing bag. In order to reduce the effort exerted by the user during inhalation and exhalation, the applicant decided to abandon the breathing bag equipped with a pressure device, included between the outlet of the absorbent cartridge and the inlet of the cooler, in favor of separately designed exhalation bag 4 and inhalation bag 8, installed at the inlet of the absorbent cartridge 5 and at the outlet of the cooler 7, respectively.

At the same time, the continuous pressing of the inhalation bag 8 is used to provide excess pressure in the inhalation part of the circulation circuit, in order to exclude the inhalation of toxic ambient gases by the user due to the possible loose fit of the face mask to the user's face. The continuous pressing of the exhalation bag 4 is used to smooth out the pressure differences at the inlet of the absorbent cartridge 5 during the inhalation phase in order to maintain in it as stable a flow of the exhaled gas mixture as possible to ensure optimal conditions for the operation of the active substance of the absorbent cartridge 5. Pressing the exhalation bag 4 also helps to maintain circulation of the gas mixture in a closed circuit. Experiments with independent pressing of the inhaling bag and the exhaling bag demonstrated good results in a stationary mode of breathing, however, when the breathing load changed, an imbalance of the closed circulation circuit occurred: depending on the direction of the change in breathing intensity, the inhaling bag and the exhaling bag either inflated or collapsed.

Therefore, according to the invention, the simultaneous pressing of the inhalation bag 8 and the exhalation bag 4 by the pressure plate 20, which is hinged without skewing towards the bag with lower pressure, is installed on the end of the spring-loaded lever 21, the other end of which is hingedly fixed on the body 1. The shape and linear relationship of the arms of the lever 21, the attachment points of the lever and spring, as well as the range of spring forces calculated and the following empirically selected such that during the filling and emptying of both bags during the user's breathing, the change in the ratio of the effective values of the lever arms provides such a change in the resulting pressure force of the plate that, with a significant range of respiratory load, a decrease in exhalation resistance at the end of the exhalation phase is steadily achieved depending on the degree of filling of the bags , a reduction in inhalation resistance, as well as a largely uniform flow through the absorbent cartridge 5 and the cooler 7 in exhalation phase and inhalation phase, due to which favorable conditions are provided for the work of the active substance of the absorbent cartridge 5 and for effective heat exchange in the cooler 7.

During the functioning of the respiratory circuit, the spring-loaded lever 21 also controls the operation of the safety valve 22 of resetting the excess volume of the respiratory mixture, connected to the exhalation nozzle 2 in front of the exhalation valve Z relative to the direction of the gas mixture flow in the respiratory circuit, as well as the pulmonary valve 18. Depending on depending on the intensity of the user's breathing, two extreme states of the respiratory system are possible:

At the exhalation stage, when the total volume of the respiratory mixture exhaled by the user into the respiratory circuit, and already present in it, exceeds the internal volume of the respiratory circuit, the exhalation bag 4 and the inhalation bag 8 are inflated and through the pressure plate 20 and the pressure lever 21 act on the valve 22, which discharges the excess of the exhaled respiratory mixture into the environment.

At the inhalation stage, when the processed breathing mixture available in the inhaling bag 8 is not enough to satisfy the user's needs, the pressure plate 20 is lowered and the spring-loaded pressure lever 21 acts on the lung machine 18, which - in contrast to the prior art - supplies oxygen from the zone 17 of medium pressure not into the bag 8 breaths, and directly into the nozzle 10 breaths, replenishing the user's need without delay in the breathing mixture.

Since the gas mixture at the outlet of the absorbent cartridge 5 has a very high temperature, which is reduced mainly in the cooler 7 with a refrigerant, to additionally reduce the temperature of the breathing mixture inhaled by the user according to the invention, a connecting element is used between the absorbent cartridge 5 and the cooler 7. For this, the circulation circuit is closed breathing mixture contains a corresponding inventive device for transferring the hot gas mixture from the outlet of the absorbent cartridge 5 to the cooler 7, its additional cooling and simultaneous removal by counterflow of condensate formed in the cooler - the so-called cooling separator 6.

In the preferred embodiment, the separator 6 (Fig. 2) is made in the form of a flexible bag 23, having an inlet pipe 24 and an outlet pipe 25, equipped with flanges for connecting to the lower parts of the absorbent cartridge 5 and the cooler 7, respectively. A channel for separating the flow of hot breathing mixture from the absorbent cartridge 5 and condensate from the cooler 7

Z is formed by the outlet pipe 25 and the perforated separating partition 26 located along the entire length of the bag. In the lower part of the bag 23 of the separator 6, under the partition 26, there is a moisture-absorbing element 27.

During the operation of the breathing circuit, the hot gas mixture flowing from the absorbent cartridge 5 passes through the cooling bag 23 to the cooler 7. At the same time, the bag 23 is designed in such a way that it is filled with the breathing mixture purified in the cartridge 5 and its walls are pressed against the back cover of the case 1, as well as to cylinder 15, transferring the heat of the breathing mixture to them.

Thanks to the application of the cooling separator b, an additional decrease in the temperature of the respiratory mixture by several degrees is achieved.

In the cooler 7, the hot gas mixture comes into contact with the cooled outer wall of the glass with the refrigerant, cools and enters the inhalation bag 8. The condensate formed in the cooler 7 on the wall of the glass with the refrigerant flows through the outlet 25 under the separating partition 26 and is collected in the moisture-absorbing element 27.

Thanks to the above-described technical solutions corresponding to the invention, a more effective treatment of the gas mixture exhaled by the user of the isolating breathing apparatus is achieved, and a better preparation of the breathing mixture inhaled by the user in a wide range of respiratory activity due to its effective cooling and rational enrichment of oxygen, as well as improvement of the user's respiratory comfort due to reducing the resistance of the respiratory circuit in different phases of the breathing cycle.

The claimed technical solutions are implemented in the latest models of the applicant's isolating breathing apparatus.

OpPMm-152

POSITION DESIGNATIONS

1 - Body 2 - Exhalation pipe

C - Exhalation valve 4 - Exhalation bag 5 - Absorption cartridge b - Cooling separator 60 7 - Breathing mixture cooler

8 - Inhalation bag 9 - Inhalation valve 10 - Inhalation pipe 11 - Inhalation hose 12 - Junction box 13 - Face mask 14 - Exhalation hose 15 - Cylinder 16 - Oxygen distribution unit 17 - Medium pressure zone 18 - Pulmonary machine 19 - Continuous oxygen supply device 20 - Pressure plate 21 - Spring-loaded lever 22 - Overpressure relief valve 23 - Separator bag 24 - Inlet nozzle 25 - Outlet nozzle 26 - Separating partition 27 - Moisture absorbent element

Claims (2)

FORMULA OF THE INVENTION 1. Isolating breathing apparatus, containing a case-knapsack, equipped with a face mask and a 25 connection box with inhalation and exhalation hoses, inside which is placed a system for processing and supplying a breathing mixture, containing breathing bags for inhalation and exhalation, an absorbent cartridge, a cooler for breathing mixture with refrigerant, oxygen supply system and forced circulation of the respiratory mixture, which includes an oxygen cylinder, oxygen distribution a unit with a reducer and a device for constant oxygen supply and a lung machine connected to the zone of medium pressure, Zo, as well as a device for creating excess pressure in the respiratory mixture circulation circuit, which is characterized by the fact that the closed respiratory mixture circulation circuit includes a hose connected in series inhaler, junction box, face mask, exhalation hose, exhalation valve, exhalation bag, absorbent cartridge, cooling separator, breathing mixture cooler, inhalation bag 35, inhalation valve, and the cooling separator contains a hollow cooling channel made of heat-conducting material, which has thermal contact with the cold surfaces of the breathing apparatus, for passing the hot respiratory mixture from the absorbent cartridge to the cooler, and a channel separated from the cooling channel for the removal of counter 40 the flow of condensate from the cooler, as well as the fact that the inhalation valve is located in the housing between the nozzle inhalation and inhalation bag, and the exhalation valve is located in the housing between the exhalation bag and the exhalation pipe, and also that the inhalation bag and the exhalation bag are placed in the upper part of the housing directly below the inhalation valve and the exhalation valve, respectively, 45 and also that the outlet of the pulmonary machine and the outlet of the constant oxygen supply device is connected to the inhalation nozzle after the inhalation valve relative to the direction of the flow of the breathing mixture, as well as the fact that the device for creating excess pressure in the circuit of the respiratory mixture, it contains a pressure plate, installed with the possibility of simultaneous mechanical action on the exhalation bag and the inhalation bag and a pneumomechanical feedback system connected to it, which 50 contains a spring-loaded lever with a variable pressure force depending on the filling breathing bags of exhalation and inhalation. 2. The apparatus according to claim 1, which is characterized by the fact that the cooling separator is made in the form of a bag made of flexible heat-conducting material, having an inlet and an outlet, equipped with flanges for connecting to the lower parts of the absorbent cartridge and 55 of the cooler, respectively, and in the lower part a separating perforated partition is installed in the bag, under which a hygroscopic element is placed to absorb condensate from cooler WITH. Apparatus according to claim 1, which differs in that the inhalation valve and the exhalation valve are structurally identical and each contain a plastic seat and a mushroom-shaped elastic petal, and the working surface of the seat is concave in the form of a fragment of the side surface of the cylinder. s shin 13 g h et et ( Her sh still iz zo every p she p, rok o friyumkim syh i oz Kk, y i zh azh iv b, s zesoya Ye he kl yari -h ho 2. tA no her dk o UM and and Z r vo X their and K 7 th i ! she m ko shk 1 z ke che it v i ? ТК я эх « - ze я ро р «3 nd, I fohzhkhk ok mkyukkyu i - шт I х ней у Я ше де I и ж ос 7 шт АХ з | shk s, zd E s oy se I dhkizhku z k zh , tel M h e ky z GA yufennnnh Koddddyuyuvinv h sa I Her pameuktktnlzhy: 4 pok V ododoyuyuh soyoyu sen -h ; : ect | I V s, and : o slnny hi | n pev now and | day V per ! Bin Ya kn Ka Sha shi y x sho yi v z X ZMnpzhizhkkkyukkkzhkkkkyu sekzhzhzhzhihy X shik Ya pek . tya ran about AI! shi - My u z se z U 7 z 1 ; ! ; 1 i z z shk i z i i i ' t i KHE A i Unshnia i 7 a p lavok ak idyuovv | et vk s i mon zh zhd llzhl dj zhzh zhzh zh kh kl zh zh zh zh ni kn nm nm -x U Uekyu I Go z pev, И7 shk 1Z nya Z kt skkkzhzhkkzhizhkzhkkkyuknyu Ko, i yi cho Ye kh nu E - ate ; - epos V Z nn, z nyu I m y a "KK ХК КК КК КК to ot Ma ih Fig. 1 te i sk v i U - Tr i dnk sche rn MKK JHE oplortlltttifonny nty KMT nina pe unk k : Y Bony i і ptn NK i: Ti Hodinu : ЧЕ i kn : X i; M: more and more; Shih and X chem and x "s i n t h e c i n h x i n x x x 2 i di kyti ttetitittittitettetetttttttttttntntnuttntnutnutnings 7: Fig. 2 b